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H U YG E N S ? S  R I N G ,  
C A S S I N I ? S  D I V I S I O N  
&
SATURN?S CHILDREN
Albert van Helden
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Text Copyright ?2006 Albert van Helden. All rights reserved.
A????? ??? H????? is Professor Emeritus at Rice University and the Univer-
sity of Utrecht, Netherlands, where he resides and teaches on a regular basis. He
received his B.S and M.S. from Stevens Institute of Technology, M.A. from the
University of Michigan and Ph.D. from Imperial College, University of London.
Van Helden is a renowned author who has published respected books and arti-
cles about the history of science, including the translation of Galileo?s ?Sidereus
Nuncius? into English. He has numerous periodical contributions to his credit
and has served on the editorial boards of Air and Space, 1990-present; Journal for
the History of Astronomy, 1988-present; Isis, 1989?1994; and Tractrix, 1989?1995.
During his tenure at Rice University (1970?2001), van Helden was instrumental
in establishing the ?Galileo Project,?a Web-based source of information on the
life and work of Galileo Galilei and the science of his time. A native of the
Netherlands, Professor van Helden returned to his homeland in 2001 to join the
faculty of Utrecht University.
Edited by Robert Kearns
Designed and typeset by Marc Alain Meadows
Meadows Design O?ce, Inc., Washington, DC, www.mdomedia.com
??????? ?? ???????? ??????????-??-??????????? ????
Van Helden, Albert.
Huygens's ring, Cassini?s division, and Saturn?s children/by Albert van Helden.
p. cm. ?  (Dibner Library lecture ; 27 October 2004)
Includes bibliographical references.
1. Telescopes. 2. Discoveries in science.  I. Title.
????.???? ????
522'.209?dc22 2006028330
HUYGENS?S RING, CASSINI?S DIVISION
AND SATURN?S CHILDREN
ture and production of this booklet. We are also grateful to Albert van
Helden, who produced both an entertaining lecture and excellent man-
uscript for future readers. We hope you enjoy it.
For more information, please see the home page of the Dibner Li-
brary of the History of Science and Technology at www.sil.si.edu/Libra
ries/Dibner/. To see Dr. van Helden?s lecture and a list of all the other
Dibner Library Lectures, go to www.sil.si.edu/exhibitions/lectures.htm.
Nancy E. Gwinn
Director, Smithsonian Institution Libraries
August 2006
[ 7 ]
F O R E W O R D
M ysterious Saturn is the subject of this intriguing essay by Al-bert van Helden, Professor Emeritus at Rice University andthe University of Utrecht. Calling Saturn ?with its system
of rings and satellites. . . the most splendid object in the solar system re-
vealed by the telescope,? van Helden shows what an important object of
research the planet has been for four centuries, made popular again with
NASA?s 2004 Cassini-Huygens Mission, which placed a probe on Titan,
one of Saturn?s satellites. Thus, the subject of the 14?? annual Dibner Li-
brary Lecture is at once historical and contemporary and shows once
again the value of the collections housed in the Dibner Library of the
History of Science and Technology.
Bern Dibner (1897?1988) is the individual responsible for bringing
together the remarkable collection of books now housed in the library
that bears his name, one of two rare book facilities among the twenty
branches of the Smithsonian Institution Libraries. An electrical engineer,
book collector, and philanthropist, Dr. Dibner donated over 8,000 vol-
umes of rare scienti?c and technological works from his Burndy Library
to the Smithsonian on the occasion of the United States Bicentennial cel-
ebration in 1976. He considered it a gift to the nation responsible for his
success. This splendid donation is the core of the Libraries? exceptional
physical sciences collection and contains many major works dating from
the ?fteenth to the early nineteenth centuries in engineering, trans-
portation, chemistry, mathematics, physics, electricity, and, as this essay
demonstrates, astronomy.
We thank The Dibner Fund for supporting the lecture series and its
publications. Sta? of the Libraries? Special Collections Department and
Public A?airs O?ce helped with various aspects of planning for the lec-
T he planet Saturn with its system of rings and satellites is themost splendid object in the solar system revealed by the tele-scope. The ring system has also been an important research
subject for four centuries. The recent Cassini mission to explore the
planet and its surrounding rings, with its embedded Huygens probe mak-
ing a spectacular landing on the intriguing moon Titan, has put the
planet once again in the popular and scienti?c news. I say ?once again,?
because in the seventeenth century the planet was also frequently in the
news. Its appearance was a scienti?c problem, and the discoveries made
about it were celebrated at courts as well as scienti?c meetings. This pa-
per is about those early years of telescopic discovery.
Between 1609 and the end of the seventeenth century, astronomy
and cosmology were profoundly changed by a new instrument, the tele-
scope. No one could have suspected that in the middle of a cosmologi-
cal debate in learned circles?about whether the Earth or the Sun was
the center of the universe?a ?ood of astounding new information
would come from an entirely new direction and would transform the
cosmological debate from a rather esoteric argument carried on by schol-?????? ?. The Aristotelian cosmos. Peter Apian, Cosmographia (Nuremberg, 1524)
H U YG E N S ? S  R I N G ,  
C A S S I N I ? S  D I V I S I O N  
&
SATURN?S CHILDREN
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place to place? In other words, one was left without physics (that is, a
causal account of why objects move as they do).Clearly, this simple
change proposed by Copernicus meant that one had to give up an en-
tire system of thought and construct a new one. That process took a
century and a half. Indeed, most students of heavenly things ignored
Copernicus?s cosmological theory and concentrated on the rest of his
book, in which he completely recast technical astronomy along helio-
centric lines. But since we, as observers, are on the Earth, not on the
Sun, we still have to refer our predictions to the Earth; and thus, one
could just treat Copernicus?s cosmological claim as a convenient math-
ematical hypothesis. Robert Westman has shown that between 1543,
when Copernicus?s book was published, and the turn of the seventeenth
century, perhaps only a dozen scholars accepted Copernicus?s theory as
representing reality.
Some of the questions that were raised by opponents of heliocen-
trism during this early period were: If the Earth is a planet, then why is
it the only planet to have a moon? Why is there more than one center of
motion/rotation in the universe? If the Copernican theory predicts that
the stars are so far away (they have to be in order to explain the lack of
annual stellar parallax), then why do they not appear smaller? In the old
cosmology there were seven planets; now, because the Moon is elimi-
nated from the sequence, there are only six?why six? These questions
strike us as strange, but they show just how uncomfortable this new cos-
mology was for people. I do not need to remind you that an Earth spin-
ning on its axis and traveling around the Sun violated their common
sense. Finally, there was the question about Scripture, which seemed
clearly to indicate that the Earth does not move. But all these questions
were matters of philosophy, hardly noticed by a larger public. Those
teaching astronomy in the universities, even if they were ?Copernicans,?
continued to teach the older earth-centered books because these were
stipulated in their contracts.
[ 11 ]
ars in Latin to a public issue on the tongues of the entire literate popu-
lation of Europe (and beyond). The telescope did not prove that the Sun
was the center and the Earth in the ?third heaven,? but the information
it injected into the deliberations made a lot more sense in the context of
a sun-centered theory. The telescope, therefore, not only changed the
terms of the debate, it answered some pressing questions about the he-
liocentric option.
The cosmos of Aristotle (?gure 1), which ruled unopposed right up
to the time of Copernicus was a thing of beauty. The Earth, stage for the
human drama, was in the center, there was a place for everything?it
was, in fact, a universe of places, not of spaces?and there was an ab-
solute divide between the heavens and the earthly regions. The heavens
were perfect and unchanging; the lower realms
were changeable and corrupt. For most, the
center of the Earth, the most corrupt place in
the universe, was the place of hell; the empy-
rean heaven, the abode of God, was situated at
the periphery. It was a beautiful structure that
gave a physical explanation but also supported
values.
Now, by the simple move of exchanging
the places of the Earth and Sun (?gure 2), Co-
pernicus undermined everything. The Earth
was now a planet in the heavens, the distinc-
tion between the corrupt earthly region and
the perfect heaven was abolished: Was the
Earth now perfect or were the heavens cor-
rupt? If, in the old system a stone fell to the center of the universe?
which is also the center of the Earth?because that was its natural place,
then how was one to explain that motion when the center of the Earth
was no longer the center of the universe and constantly moving from
[ 10 ]
?????? 2. The cosmos acording to
Copernicus. De Revolutionibus
Orbium Coelestium (Nuremberg,
1543).
Galileo?s discoveries were wondrous and new and they were on the
tongues of everyone. Since Galileo tied them to the Copernican theory,
that theory was now publicly and widely discussed as well. Galileo went
on to share the discovery of sunspots in 1611, and engaged in a public
debate?a battle of books?with a German Jesuit named Christoph
Scheiner, who argued that the spots are satellites of the Sun, thus saving
its perfection. With words, pictures, and diagrams, Galileo showed the
Jesuit to be wrong, and came out four-square in favor of the Copernican
theory. We all know where this eventually led Galileo and will not fol-
low him there; however, there is one lesser-known discovery that ties him
to events later in the century.
In July 1610, Galileo ?rst observed Saturn with a telescope. To his
amazement, the planet showed not a single disk, but rather three: a cen-
tral one closely ?anked by two smaller ones. He thought that
perhaps the two companions were satellites, although clearly a
di?erent sort of satellite from those of Jupiter (?gure 4).1 The
companions, however, did not move with respect to the central
body, and Galileo lost interest for the moment. Two years later,
when he was working on sunspots, he again examined the
planet and to his surprise found the lateral bodies gone: had Sat-
urn devoured his children?2 He discussed this mysterious phe-
nomenon in his sunspot letters and made a complicated prediction of
their reappearance. They reappeared as he had predicted, but since they
then showed no change he lost interest again; until several years later, in
1616, he observed Saturn again and found its appearance to be as shown
in ?gure 5. The lateral bodies had grown into two ?half eclipses,? as he
called them.3 He could make little sense out of Saturn?s appearances, and
left them as a puzzle to be solved by his successors.
Telescopic astronomy did not become a regular part of astronomy
immediately. For one thing, excellent research instruments?by the
standards of the time?are always expensive. But for another, it was not 
[ 13 ]
It was into this situation that the telescope was introduced. First made
public in the Dutch Republic, low-powered spyglasses quickly spread over
Europe. In Padua, Galileo Galilei, professor of Mathematical sciences at
the university there, seized on the device and quickly turned it into a high-
powered scienti?c instrument?slightly more powerful than our ordinary
binoculars. And with it, he reaped a rich harvest of phenomena that lie
just slightly beyond the power of the naked eye. These were as follows:
x The surface of the Moon is not perfectly spherical, as be?ts a heav-
enly body, but rather is mountainous.
x Planets are resolved into little discs, like full moons; ?xed stars be-
come brighter but remain points.
x There are innumerable ?xed stars invisible to the naked eye, and neb-
ular areas like the Milky Way can be resolved into individual stars.
x Jupiter has four moons.
Galileo argued in Sidereus Nuncius (1610) that the Moon is like the
Earth (?gure 3), as one might expect if Copernicus was right; that ?xed
stars were clearly much farther away than the planets, as was implicit in
Copernicus?s theory; that the Earth was by no means
the only planet with a moon, and that, regardless of
what cosmological system one believed in, there was
more than one center of motion in the universe. A few
months later he also revealed that the telescope
showed that Venus goes through phases, just like the
Moon, and, therefore that planet?and by implication
Mercury?goes around the Sun. Thus, there were at
least three centers of motion: the Earth, the Sun, and
Jupiter. These phenomena hardly ?tted into the old
Aristotelian cosmology, and Venus?s phases proved that scheme wrong.
But none proved that the Earth moves and the Sun stands still. That
proof was centuries in coming.
[ 12 ]
?????? 3. Galileo?s 
observation of the Moon
(?rst quarter). Sidereus
Nuncius (Venice, 1610).
?????? 4. Galileo?s 
sketch of Saturn?s 
appearance, July 1610. 
Le Opere di Galileo
Galilei, X: 410.
immediately clear where the research with this new instrument should 
be located. It was an optical?that is, mathematical?instrument with
which cosmological?that is, philosophical?
issues were investigated. Thus, one of Christiaan
Huygens?s most faithful correspondents, Ismael
Boulliau (1604?1696) occasionally observed with
a telescope, but for the most part occupied him-
self in his spare time with astronomical models
and tables. The Dibner Library has a letter from
Huygens to Bouliau, dated 25 September 1659.
Among a new generation of observers that
grew up with the telescope were Pierre Gassendi and Johannes Hevelius.
Both these men regularly observed the heavens with their telescopes.
And it was after Saturn had once again appeared without its appendages,
in 1642, that they led a generation of observers in a concerted attack on
the problem of Saturn. Their recorded observations (?gure6) give some
idea of the results. Given our knowledge, we can easily judge some of
these to be better than others, but observers who did not know what
caused Saturn?s appearances were at a loss. The more so, because a fun-
damental dichotomy ran through the problem: Ever since Galileo three
decades earlier, observers had believed in what we might call a satellite
model (see, for instance, ?gure 7), and somehow the ?handled? appear-
ance had to be ?t into this model. This was a very tall order indeed. It
was not until the situation was reversed?that is, the tricorporeal (or
satellite) appearance had to be explained in terms of the handled ap-
pearance?that proposed solutions came.
The breakthrough came from The Hague, where Christiaan Huy-
gens and his brother Constantijn had begun making telescope lenses in
1654. They quickly progressed to the skill level required to make research
telescopes, and Christiaan began exploring the heavens with a 12-foot
e?ort that magni?ed 50 times, ?nished in February 1655. By the end of
[ 14 ]
?????? 5. Galileo?s sketch of
Saturn?s appearance, 1616. Opere,
XIII: 276, note 1.
?????? 6. Observations of Saturn by: top left, Johannes Hevelius (Selenographia
[Gdansk, 1647]); top right, Givanno Batista Odierna (Protei Caelestis Vertigines
[Palermo, 1657]); center, Francesco Fontana (Novae Colestium Terrestriumque Rerum
Observationes [Naples 1646]); bottom, Eustachio Divini (Broadsheet 1649).
After observing the moon for several circuits around Saturn, Huy-
gens sent an anagram to a few of his correspondents, a line from Ovid?s
Fasti with a few extra letters added: Admovere oculis distantia sidera
nostris vvvvvvv ccc rr hnbqx.5 This, he thought, would safeguard his
claim to priority. He then went on a long trip to France, where he told a
few scientists of his discovery, returning to The Hague near Christmas
1655. At that time Saturn was in conjunction with the Sun, and when it
appeared again in January 1656, the anses had completely disappeared.
Some time late in 1655 or early 1656, Huygens found the solution to the
puzzle that had ba?ed observers since Galileo. An important clue was
that the anses did not become shorter as they grew thinner, as we can
see from Huygens?s earliest surviving observation, made in March 1655
(?gure 8). He was to explain his reasoning in Systema Saturnium (see p.
00), but for the moment it is
important to note that when
he solved the puzzle Saturn
was either in conjunction with
the Sun or completely shorn
of its anses. He saw a ring in
his mind?s eye, not through his
telescope.
While continuing his e?orts to make better and better telescopes,
Huygens published a brief tract entitled De Saturni Luna Observatio Nova
(1656), in which he described his discovery of the new moon and gave an
anagram that contained the solution to the problem of Saturn, a a a a a
a a c c c c c d e e e e e h i i i i i i i l l l l m m n n n n n n n n n o o o o p p
q r r s t t t t t u u u u u, ?so that if perhaps someone may think that he
has found the same thing, he will have the time to make it known, so that
it will not be said that he borrowed it from us, nor we from him.?6 The
complete treatment of the newly discovered moon as well as his theory
was, however, not quick in coming. During this period, Huygens man-
[ 17 ]
March, he had found a satellite of Saturn. We may ascribe this discovery
partly to the quality of his telescope and partly to luck. Over the years,
after Galileo?s discovery of the four moons of Jupiter, several observers
had claimed to have discovered other satellites, either of Jupiter, Mars,
or Saturn. Each time, the claims were debunked by other observers.
There was perhaps a feeling that, as Wren put it, ?all celestial mysteries
were at once disclosed to [Galileo].?4 There was little left for his succes-
sors to discover, and it may very well be that no one besides Huygens
was looking for satellites. Huygens was lucky because, as the planet?s
anses were getting thinner and thinner, its moon was behaving more and
more like the moons of Jupiter, traveling in a straight line back and forth
around Saturn. When the anses form a broader ellipse, the moon de-
scribes an oval path around Saturn and is not easily distinguished from
nearby ?xed stars.
[ 16 ]
?????? 7. Saturn?s appearances explained by the satellite model. Christoph Scheiner,
?Tractatus de Tubo Optico,? Munich, Bayrische Staatsbibliothek MS Clm. 12425, p. 64.
?????? 8. Christiaan Huygens?s ?rst recorded observa-
tion of Jupiter and Saturn, March 1655. Oeuvres Com-
pl?tes de Christiaan Huygens, I: 322.
aged to successfully connect a pendulum to a clock and develop the re-
sulting pendulum clock (which improved the accuracy of clocks by an
order of magnitude); privileges had to be applied for the clock and the
book Horologium (1657) took priority. Then there was also the need to
wait for others to come forward with theories concerning Saturn?s ap-
pearances. And throughout, Huygens continued his observations of the
satellite to determine its period more accurately, while simultaneously
continuing his observation of the planet and the ring in order to estab-
lish the inclination of the ring-plane to the ecliptic and the equator as
well as the direction of the major axis of the apparent ellipse of the ring.
Systema Saturnium did not appear until the summer of 1659.
Between the time Huygens found the solution to the problem, in
1655/56, and the appearance of Systema Saturnium, more than three
years later (?gure 9), others did come forward with their theories. The
famous Polish astronomer Johannes Hevelius, for whom establishing
the period of the changing appearances was the most important aspect
of the problem of Saturn, published Dissertatio de Nativa Saturni Facie in
1656, in which he argued that Saturn consisted of an ellipsoidal central
body to which the anses were attached. The entire formation rotated
around the minor axis as shown (?gure 10). The next year, the Sicilian
priest and astronomer Giovanni Battista Odierna published Protei
coelestis vertigines seu Saturni Systema (see ?gure 6 on page 67), in which
he theorized that Saturn was an ovoid body with two dark spots on it
that rotated on an axis. Meanwhile, the Parisian mathematician Giles
Personne de Roberval outlined a rather di?erent sort of theory in a let-
ter to Huygens. According to Roberval, the appearances of the anses
were caused by vapors that emanated from a ?torrid zone? and collected
around Saturn?s equatorial plane. When the space above this zone is
completely ?lled with vapors, Saturn appears oval, and when there is
space left between the exhalations and the planet?s surface, Saturn ap-
pears ?anked by two ?stars.? If the exhalations are so thin that they are
[ 18 ]
?????? 9. Christiaan Huygens?s Systema Saturnium (The Hague, 1659).
transparent, the planet will appear round and without its appendages.
By far the most interesting theory, which remained unknown to
Huygens until 1661, was developed by the mathematician (and later ar-
chitect) Christopher Wren. In 1658, spurred on by Huygens?s challenge
and anagram, Wren wrote a little tract entitled De Corpore Saturni. In it
he theorized that an elliptical ?corona? was attached to Saturn?s body
(see ?gure 11), and that the entire formation rotated or librated around
its major axis. Wren could explain Saturn?s appearances reasonably well
[ 20 ]
?????? 10. Johannes Hevelius?s explanation of Saturn?s appearances. De Nativa
Saturni Facie (Gdansk, 1656).
?????? 11. Christopher Wren?s theory of Saturn?s appearances. ?De Corpore Saturni,? 1658.
Huygens explained how he arrived at the ring-hypothesis. Our Earth
spins on its axis once a day, while the Moon goes around us once a
month. By analogy, if Saturn?s moon has a period of sixteen days, then
the planet must spin on its axis in a much shorter period. And this means
that all the matter between Saturn and its moon must rotate around that
same axis in times intermediate between 16 days and perhaps a day. Al-
though Huygens does not say this, the in?uence of Ren? Descartes (who
visited the Huygens family home several times) is apparent: Huygens was
thinking in terms of vortices. All planets are at the centers of their own
sub-vortices, while they all go around the Sun in one big vortex. But that
meant that the anses, whatever their shape, had to revolve around Sat-
urn?s axis of rotation with a very short period. Changes in their appear-
ances, however, happened very slowly, with a period of about 14 years,
not in a few days. The anses therefore had to be symmetrical about Sat-
urn?s axis of rotation; a ring satis?ed that requirement. At this point,
Huygens presented the solution to the anagram he published three years
earlier in De Saturni Luna Observatio Nova: annulo cingitur, tenui, plano,
nusquam cohaerente, ad eclipticam inclinato, or ?It is surrounded by
a thin, ?at ring, touching it nowhere, and inclined to the ecliptic.?9
The next order of business was to establish certain parameters, such
as inclination of the ring-plane to both the equator and ecliptic. He made
the ring roughly parallel to the plane of the (Earth?s) equator and placed
its intersection with the ecliptic at 20_? Pisces and Libra. Having deter-
mined these points, he could explain when and where the ring could give
rise to all the appearances observed over the years (?gure 12), with the
exception, of course, of those that were the result of primitive telescopes
or observer error. Predicting when and in what part of the zodiac the
ring would again be invisible was straightforward. But why the ring
should be invisible was, for Huygens, rather tricky, because he believed
the ring to be a solid structure which, although comparatively thin, was
nevertheless several thousand miles thick. When the ring was edge-on it
[ 23 ]
with this hypothesis, and he had an interesting explanation of the fact
that this corona periodically became invisible: It had ?no sensible thick-
ness, although it is perhaps a few miles thick.? Therefore, ?[i]ts thickness
is not su?cient to be see in any way by the inhabitants of the Earth, and
for this reason the corona may be taken as a mere surface.?7
Wren wrote this in 1658. When, early in 1659, Huygens informed his
English colleagues of his ring-theory, Wren put the manuscript away.
When he was asked about his theory a few years later, he explained why
he had not pursued it further:
. . . when a shorte while after, the Hypothesis of Hugenius was sent over in writing,
I confesse I was so fond of the neatnesse of it, & the Naturall Simplicity of the con-
trivance agreeing soe well with the physical causes of the heavenly bodies, that I loved the
invention beyond my owne & though this [hypothesis] be so much an equipollent with
that of Hugenius, that I suppose future observations will never be able to determine which
is the trewest, yet I would not proceed with my designe. . . . 8
In the summer of 1659, Systema Saturnium ?nally appeared. Huygens
had already explained his ring-theory to his French and English col-
leagues by this time, but if expectations of the book were high, the
reader was not disappointed: In sheer amount of celestial novelty Sys-
tema Saturnium rivaled Galileo?s Sidereus Nuncius published half a century
earlier. Huygens described his telescopes, showed observations of the
belts and zones of Jupiter (observed earlier by others), details on the sur-
face of Mars, and the Orion nebula (missed by Galileo) with three of the
four stars now known as the Trapezium. Huygens then turned his 
attention to Saturn. He ?rst discussed all his observations of the new
moon made over a period of four years and derived its period. Then he
discussed Saturn?s appearances published by others, beginning with
Galileo, explaining away or rejecting appearances that would not ?t the
hypothesis he was about to put forward. Only after this process did he
come to his ownexplanation of Saturn?s appearances.
[ 22 ]
was invisible, Huygens argued, because its outside edge was covered with
a material that did not re?ect light. He interpreted the dark line he had
seen across Saturn?s disc during the round appearance of 1655?56 (?gure
13) as the ring?s dark outside edge.
Huygens ended Systema Saturnium with an important digression on
the sizes and distances of the planets: How would the solar system ap-
pear to an inhabitant of Saturn? For the answer, he needed to know the
absolute sizes and distances of the planets. First, he explained how one
could measure a planet?s angular diameter. In the ?astronomical? tele-
scope used by Huygens, one with a convex eyepiece, the rays come to a
focus inside the tube. If one places an object in the focal planet, it will
appear in focus and superimposed on the image of the object one is ob-
serving. Huygens put an aperture stop in this plane, measured its angu-
lar size by timing the progress of a star across it (while holding the tele-
scope ?xed)?he found it to be 17_ minutes of arc?and then, when he
observed a planet, he would insert thin copper rods into the focal plane
until he found one that just covered the planet?s disk. Knowing what frac-
tion of the aperture was covered by the thickness of the rod, he could
easily determine the angular diameter of the planet. Now, the ?rst full-
?edged micrometer had been made by William Gascoigne in England
two decades earlier, but it was still unknown to the astronomical com-
munity. Huygens here published the principle of the micrometer, and
the wire micrometers made in the next decade by French astronomers
were the result of this passage in Systema Saturnium.
Having measured the angular diameters of all planets except Mercury,
and knowing the relative distances of the planets from the Sun, Huygens
now knew how large the planets were with respect to the Sun. He
needed one absolute measure to turn all relative sizes and distances into
absolute ones. There was, as yet, no way to make such a measurement,
so Huygens made an argument from harmony. The sizes of the planets
roughly increase with their distances from the Sun, except that Huygens
[ 25 ]
?????? 12. Huygens?s diagram to explain Saturn?s appearances. 
Oeuvres Compl?tes, XV: 309.
?????? 13. Huygens?s observation of Saturn in the winter of 1655?56, 
when the anses were invisible. The dark line, which is the shadow of the ring on the
planet?s body, was interpreted by Huygens as the dark exterior edge of the ring.
Oeuvres Compl?tes, XV: 247.
found Jupiter to be larger than Saturn and Venus larger than Mars. Nev-
ertheless, he assumed the Earth to be intermediate in size between Mars
and Venus. Since Mars?s diameter was 1/166?? part of the Sun?s and
Venus 1/84?? part, Huygens took the mean between these two fractions
and arrived at a terrestrial diameter 1/111?? the Sun?s?an ?accurate
guess.? This meant a solar distance of about 25,000 terrestrial radii, or,
in modern ?gures, roughly 100 million miles. This corresponds to a so-
lar parallax of 8.2".10 Huygens now had a complete scheme of sizes and
distances in the solar system, and shortly after Systema Saturnium had ap-
peared, he found a way to present his results visually (?gure 14).
Systema Saturnium was then, a book about much more than just the
problem of Saturn, but it was about Saturn that he received most criti-
cism. No single construction of the anses could account for every single
appearance of the planet found in the literature, and Huygens had there-
fore criticized and dismissed a number of them. But how could he jus-
tify his judgments? He argued:
In this investigation, we ask that it is conceded that, because we were the ?rst to de-
tect the companion of Saturn with our telescopes and clearly see it whenever we wish,
therefore our telescopes must be preferred to those of others who, although daily engaged
in observing Saturn, were nevertheless unable to reach that star; and that therefore the
results of our observations of the shape of the planet must be judged to be truer each time
when the di?erent shapes were simultaneously observed by us and by them.11
This was a clever argument, and Huygens may have believed it him-
self. For those with mediocre telescopes it was undoubtedly true, but to
observers whose telescopes were among the best in Europe?and whose
reputations were based on the excellence of their instruments?Huy-
gens?s claim was an insult and a challenge. For them there was a di?er-
ence between not having observed Saturn?s moon earlier and not having
telescopes good enough to show it. Johannes Hevelius pointed out that
he had observed the satellite a decade earlier but had taken it to be a ?xed
[ 26 ]
?????? 14. Huygens?s representation of the sizes of the planets relative to the Sun. 
Oeuvres Compl?tes, XV: 374.
an opportunity to raise the cosmological issue. Together they composed
(but published with only Divini?s name on the title page) Brevis Annotatio
in Systema Saturnium Christiani Hugenii (Rome 1660), likewise dedicated
to Prince Leopold. Divini argued the 
superiority of his telescopes?he, too,
could easily see Saturn?s moon?and
Fabri attacked Huygens?s Copernican-
ism while proposing another explan-
ation of Saturn?s manifold appearances.
He supposed a satellite model in which
two sets of satellites, one pair light-ab-
sorbing and the other light-re?ecting, re-
volved about points behind Saturn, (see
?gure 15). Divini (and Fabri) stated that
they ?eagerly submitted their ideas to
[Prince Leopold?s] very just censure and
clear judgment.?15
These two books put Prince Leo-
pold in an awkward position. On the one
hand, there was an elegant hypothesis
put forward by a heretic and Coperni-
can; on the other, there was a rather silly
hypothesis put forward by a member of
a powerful order committed to preserv-
ing the Christian-Aristotelian cosmology.
The Galileo process of 1633 had power-
fully demonstrated the end to Florence?s power to thumb its nose at
Rome, and in Fabri?s text, several instances seemed directly to refer to
the Galileo a?air. In explaining Fabri?s hypothesis, Divini (sic) began with
the following proposition: ?The Earth is immobile at the center of the
world and the celestial spheres revolve around it. This is an opinion that
[ 29 ]
star. As he wrote to his friend Ismael Boulliau, ?And therefore I see no
reason why our observations do not merit the same faith as those of
Huygens.?12 His telescopes were just as good as those of Huygens, and
as far as his eyesight and his claim that Saturn?s central body was ellip-
soidal was concerned: ?[D]oes Huygens perhaps suppose that I and oth-
ers cannot see the di?erence between elliptical and spherical, or that it
was invented by my mind . . .or rather that I dreamed it? No, by Hercu-
les!?13 But having vented his rage to Boulliau, Hevelius expressed his dis-
agreement to Huygens himself in very measured tones. Their relations
remained cordial.
An entirely di?erent approach was taken by Eustachio Divini (1615?
1675) in Rome, considered by many to be the ?nest telescope maker of
Europe. Huygens had criticized Divini?s illustration of Saturn published
in 1649 (see ?gure 6 on page 67) not for its shape, but for the spurious
shadow e?ects: ?Since he is considered a most excellent telescope-maker,
it is credible that he has described the actual shape of Saturn best of all,
except for the shadows that appear in the ?gure which, in my opinion,
were added by him.?14 This statement was hardly a criticism, and Divini
easily could have blamed the problem on the engraver. But Huygens?s
claim of authority was another matter. Divini had won his eminence in
his trade by great skill and hard work, taking on all challengers. His best
telescopes were among the collection of instruments of the Florentine
Accademia del Cimento of Grand Duke Ferdinand II and his brother
Prince Leopold. It was to Leopold that Huygens had dedicated Systema
Saturnium, and thus Huygens?s authority claim was all the more serious
for Divini: Was he no longer the best telescope maker in Italy, or Europe?
But in Rome there were other problems (or rather opportunities?)
raised by Systema Saturnium and its author. As a Dutchman, Huygens was
a Calvinist heretic, and moreover in his book he took the centrality of
the Sun as given. And therefore, if Divini wanted to strike a blow against
Huygens?s pretensions as a telescope maker, the Jesuit Honor? Fabri saw
[ 28 ]
?????? 15. Honor? Fabri?s explanation of
Saturn?s appearances, from Eustachio Divini?s
Brevis Annotatio in Systema Saturnium
(Rome, 1660). GC represent?s Saturn, HN and
SD light-absorbing satellites, and LK and RE
light-re?ecting satellites.
he defends with tenacity, judging it as conforming to Catholic decrees,
to Sacred Scripture, to the observed phenomena, and to sane reason.?16
And as if to once more drive home the restricted authority of the math-
ematician in cosmological matters, Fabri let it be known that he did not
defend his model as a true explanation of Saturn?s appearances, but
rather held it ?only as one hypothesis of many that can save the appear-
ances hitherto observed by the Astronomers.?17
Prince Leopold and his academy found a neat way out of their
dilemma. Following the Accademia del Cimento?s motto, provando e
riprovando, ?to test and test again,? they decided to settle the issue ex-
perimentally. Models of both hypotheses were built, and these were ob-
served from various distances with the naked eye and telescopes of var-
ious powers?and not only by scientists, but also by people who had no
idea what they were looking at. The results of these comparisons were
clear. The model of the ring hypothesis (?gure 16) could produce the so-
called ?trispherical? appearance that Galileo had ?rst seen, but the model
of Fabri?s ?satellite? hypothesis could in no way produce the ?handled?
appearance. In one respect, however, Huygens?s ring could not bear away
the approval of the academicians. Since they could not think of ?any ex-
ample in Nature of a material so unapt for the re?ection of light,? they
were reduced to making the ring as thin as possible and thoroughly re-
moving all roughness of its surface, for even surface irregularities that
were, in proportion to the model any higher than the highest mountains
on Earth would be seen as in thin bright line when the ring was in the
edgewise aspect.
Reports were sent to Huygens and Fabri, with an admonition from
Prince Leopold to keep them con?dential. At the same time, Huygens
published a rebuttal to Divini and Fabri, entitled Brevis Assertio Systema-
tis Saturni sui,18 which he issued together with a reprint of Brevis Anno-
tatio (1660), and his correspondents congratulated him on showing up
the foolishness of the Roman telescope maker. The next round from
[ 30 ]
?????? 16. Model of Huygens?s ring-theory made by the Accademia del Cimento.
Oeuvres Compl?tes de Christiaan Huygens, VI: 000.
generally accepted. On the basis of his mathematical work, his telescopic
astronomy and his invention of the ?rst successful pendulum clock, Huy-
gens was invited by Jean Battiste Colbert, Louis XIV?s minister, to be-
come a member of the newly founded Acad?mie Royale des Sciences
and give it intellectual leadership. When he moved to Paris in 1666 to take
up the appointment, he was perhaps Europe?s most famous scientist.
Giovanni Domenico Cassini (1625?1712) was born in Perinaldo in Lig-
uria, and educated in a Jesuit college in Genoa.19 Because of his bril-
liance, he attracted the attention of powerful patrons, and in 1649, at the
age of 25, was appointed to the chair of astronomy at the University of
Bologna. Here he was in?uenced by Giovanni Battista Riccioli, profes-
sor at the Jesuit College, who was completing his massive Almagestum
Novum (Bologna, 1651), a complete review of astronomy. Cassini quickly
learned what the burning issues in technical astronomy were, and he at-
tacked several of these. The meridian laid down in the cathedral of San
Petronio by Egnatio Danti in the sixteenth century had fallen into disre-
pair, and Cassini completely rebuilt it. The result was the meridian (or
gnomon) much the way we still see it today. Cassini?s achievement was
one of the centerpieces of the celebration surrounding the arrival of
Queen Christina of Sweden, who passed through the city on her way to
Rome in 1656. But Cassini also made careful measurements. Upon com-
paring solar declinations measured on the meridian with his measure-
ments of the altitude of the Pole, he found a discrepancy of 2 arc-minutes.
He concluded that this discrepancy was due to faulty positional correc-
tions for atmospheric refraction and solar parallax, and this meant that
the value for the obliquity of the ecliptic given by the great Tycho Brahe
might be in error by two arc-minutes (2' )?an error that a?ected not
only position measurements, but also the theories of all the planets. This
became an important part of Cassini?s research agenda, and he was to
return to the problem again and again. For the time being, he made his
new positional corrections part of a new set of tables published in 1661.
[ 33 ]
Rome, Pro sua Annotatione in Systema Saturium Christiani Hugenii (Rome
1661) did not deserve a reply. Fabri here had added two further light-
re?ecting satellites behind Saturn in order to more closely approximate
the planet?s handled appearance, but clearly things were getting silly. The
more so because Divini/Fabri admitted that he could not help seeing a
ring when he now observed Saturn. Huygens had clearly won the argu-
ment, Prince Leopold had retained his neutrality, and Fabri went on to
other challenges. The big loser was Divini. For one thing, in making ac-
tual observations of Saturn, the academicians in Florence had used a
long telescope by Divini, and had found the objective lens inferior. They
had taken it out and substituted an objective made by Evangelista Torri-
celli made more than a decade earlier. And with that combination, they
had for the ?rst time observed the shadow of the ring on Saturn?s body?
a powerful con?rmation of the correctness of Huygens?s theory. Worse
was to come for Divini. In 1662, a mysterious telescope, said to be made
in the Netherlands, began to be shown in Rome and proved to be better
than any instrument made by Divini. This was the ?rst move in a care-
fully choreographed campaign by Giuseppe Campani and his brothers
to undermine and ridicule Divini on his own turf. They succeeded: By
1665 Campani had replaced Divini as Europe?s premier telescope maker.
If Huygens had defeated the telescope maker Divini and the scholar
Fabri with comparative ease, telescopes by Campani in the hands of the
astronomer Giovanni Domenico Cassini would, as we will see, prove to
be a more formidable challenge. For the time being, however, Huygens
ruled supreme as a telescopic astronomer. He had made the ?rst addi-
tion to the number of bodies in the solar system since Galileo, and solved
a problem ?rst posed by Galileo with a breathtakingly elegant solution,
accepted by everyone in short order; although the parameters, the rela-
tive diameters of the ring and body, and the inclination of the ring plane
to the ecliptic and equator had to be adjusted and Huygens?s explanation
of the ring?s invisibility when its plane passed through the Earth was not
[ 32 ]
his eye naturally fell on Cassini. But getting the Pope?s astronomer to
Paris was by no means an easy task. Through diplomatic channels, Col-
bert let it be known in Rome that ?His Most Christian Majesty has ex-
pressed the desire to have Mr. Cassini there [Paris] for some time.21? Af-
ter some negotiations, His Holiness let Cassini go, and he arrived in Paris
in 1669 to start a new chapter in his life.
Cassini quickly made his in?uence felt in Paris. Modi?cations were
made to the (as yet un?nished) observatory; to make it more suitable for
[ 35 ]
Cassini?s hard work, organizing ability, and political acumen were re-
warded with preferments. The Pope, overlord of Bologna, appointed
Cassini inspector of papal forti?cation and then also as his engineer to
look after the papal interests in the eternal arguments about water rights
and the courses of rivers between cities in the Po valley and between the
Papal states andTuscany. In these capacities, Cassini traveled a great deal
and often was in Rome. He was there in 1664 when Giuseppe Campani
challenged Eustachio to a paragone (comparison) to decide whose tele-
scopes were better. Cassini took part in these trials, and if the immedi-
ate results showed that Campani telescopes were better than those of Di-
vini, Cassini?s personal preference for Campani telescopes was one of the
decisive factors in Campani?s lasting fame. In Rome, in 1664, Cassini and
Campani made a series of telescopic observations, published in a little
book entitled Ragguaglio di due nuove osservazioni and a broadsheet show-
ing observations of Jupiter and Saturn. The most remarkable of these
showed shadows of Saturn?s ring on its body and vice versa, the fact that
the outside of the planet?s ring was darker than the inside, and the shad-
ows of Jupiter?s satellites on Jupiter?s body. With these publications, Cam-
pani?s fame rapidly spread to all parts of Europe where there was inter-
est in astronomical observations.
Over the next several years, as his duties took him to many places in
Italy, Cassini made observations with a 17-foot Campani telescope, an in-
strument given him by the maker himself. With this very ?ne instru-
ment, he observed the planets whenever possible, including the forma-
tion of Jupiter?s satellites and their immersions in, and emersions from
Jupiter?s shadow. The result was an important series of publications, the
most important of which were two works on, respectively, surface mark-
ings and the rotation periods of Jupiter and Mars, and a set of tables of
the motions of Jupiter?s moons.20 Cassini?s reputation was rapidly grow-
ing (?gure 17), and when Colbert began looking for an astronomer to
lead the new observatory that was being designed by Claude Perrault,
[ 34 ]
?????? 17. Portrait of Giovanni Domenico Cassini, ca. 1665?1669. 
Ventimiglia, Biblioteca Aprosiano.
and half that much to its Mediterranean coastline.23 Legend has it that
upon seeing this new map Louis XIV complained that he was losing
more territory to his astronomers than to his en-
emies. Si non ? vero ? ben trovato. With Campani
telescopes, Cassini discovered the division in Sat-
urn?s ring in 1676 (?gure 18), and during the next
edgewise aspect of Saturn?s ring he discovered
yet two more moons of the planet (now called
Tethys and Dione).
Huygens?s career at the Acad?mie was not as
happy. In 1671?2, at the time when his portrait
was painted by Caspar Netscher (?g 19), he had to return to The Hague
to recover from a bout of melancholia; in 1673 he published his opus mag-
num, Horologium Oscillatorium, dedicated to the Sun King at a time when
France (along with several other countries) was at war with the Dutch
Republic. In 1675 he once again had to absent himself for more than a
year because of melancholia, and in 1681 he again returned to The Hague
with the same a?iction. That time, however, his return to Paris was
more di?cult, as the tide was running against the Protestants in France.
The death of Colbert in 1684 and the repeal of the Edict of Nantes the
following year eventually made his return impossible. So, as Cassini went
from victory to victory, Huygens faded away. The con?dent Cassini with
his Campani telescope, who came in 1669 had turned into the brilliant
astronomer of a decade later; who by gesture claimed the observatory
as his own (see ?gure 20). He was the brilliant courtier who could have
the water tower of Marly moved to the grounds of the observatory in
order to accommodate the very long ?tubeless? telescopes with which
he continued his amazing series of discoveries. Cassini married at the age
of ?fty and trained his only son to become his successor as director of
the observatory. He brought a nephew on his mother?s side, Giacomo
Filippo Maraldi, to join the sta? of the observatory. In 1794?95, Cassini
[ 37 ]
astronomical observations, he ordered powerful telescope lenses from
Campani in Rome; and he intervened in the plans for an astronomical
expedition to the tropics. His ?rst major success was the detection of two
new moons of Saturn during the ring?s edgewise aspect of 1671?72 (satel-
lites now called Iapetus and Rhea). The expedition to Cayenne by Richer
(1763), it is well-known, resulted in the discovery that a pendulum of a
given length has a shorter period in the tropics than at mid-latitudes. But
at the time it was more important that by measurements of solar decli-
nations Richer proved that Tycho Brahe had indeed made an error of
two entire arc-minutes (2' ) in the obliquity of the ecliptic. Also during
this expedition, while taking advantage of a favorable opposition of
Mars, Cassini?s simultaneous measurements of the planet?s positions in
Europe and Cayenne led to a downward adjustment of solar parallax to
about ten arc-seconds (10"), a value Cassini had been advocating for some
time because it led to a better combination of corrections for atmos-
pheric refraction.22
In the meantime, Cassini had sent Jean Picard to Uraniburg, the re-
mains of Tycho Brahe?s observatory, to check the latitude and longitude
of that observatory, so that Tycho?s observations could be referred to the
coordinates of Paris. For these observations, simultaneous observations
of the eclipses of Jupiter?s satellites were used. With a view to correct-
ing the large errors in positions of faraway places, Cassini over time es-
tablished a worldwide network of correspondents who sent him obser-
vations of Jupiter?s satellites. This is not to say that errors nearer home
were not equally troublesome. Jean Picard had published his Mesure de la
Terre in 1671, which established the length of a degree at the latitude of
Paris, but the locations of cities in France still left a lot to be desired.
Wherever Cassini and his astronomers went in France, they observed the
eclipses of Jupiter?s satellites, and slowly the contours of France were
corrected to a point where a revised map of France (not ?nally published
until 1693) made adjustments of a full degree on France?s Atlantic coast
[ 36 ]
?????? 18. Cassini?s observation
of the gap in Saturn?s ring, now
called Cassini?s Division. Journal
des S?avans, 4 January 1677.
undertook a trip to Italy, where he updated the meridian of San Petro-
nio in Bologna. It was a veritable victory tour for the most powerful sci-
entist in Catholic Europe, progenitor of four generations of Cassinis,
who ran the French observatory until the French Revolution.
Huygens fades somewhat in this comparison. But although it cer-
tainly is true that Cassini, the brilliant courtier and energetic organizer,
outshone Huygens at the French Court, it is equally true that Huygens
was the more profound thinker and brilliant mathematical scientist.
When a systematic error was discovered in the times of the eclipses of
the ?rst satellites of Jupiter, the period of which was equal to Jupiter?s
[ 39 ]
?????? 19. Portrait of Huygens by Caspar Netscher, ca. 1671. The Hague: Haags Historisch Museum.
?????? 20. Portrait of Cassini ca. 1675 
(provenance to follow)
N O T E S  
1 Galileo to Belisario Vinta, 30 July 1610, Le Opere di Galleo Galilei, Edizione
Nazionale. 20 vols. ed. Antonio Favaro (Florence:Giunti, 1890?1909; reprints
1929?1939, 1964?1966), ?: 410.
2 Galileo?s third sunspot letter, 1613. Ibid., ?: 237.
3 Galieo to Federico Cesi, cited in Giovanni Faber to Frederico Borromeo, 3
September 1616. Ibid., ????: 276.
4 Christopher Wren, ?De Corpore Saturni? (1658). See Albert van Helden,
?Christopher Wren?s De Corpore Saturni,? Notes and Records of the Royal Soci-
ety of London, 23 (1968): 213?229, at 219.
5 Ovid, Fasti Book I, line 305. ?They brought the distant stars closer to our
eyes.? Huygens sent this anagram to a few correspondents in March 1655, and
in 1656 sent them the solution: ?Saturno luna sua cicunducitur diebus sexdecim
horis quatuor,? or ?Its moon goes around Saturn in sixteen days and four
hours.?
6 Christiaan Huygens, De Saturni Luna Observation Nova (The Hague, 1656),
Oeuvres Compl?tes 15: 177
7 Van Helden, ?Christopher Wren?s De Corpore Saturni,? (note 4), 284, 285.
8 Christopher Wren to Sir Paul Neile, 1 October 1661 ( Julian). See C. A. Ronan
and Sir Harold Hartley, ?Sir Paul Neile, F.R.S.,? Notes and Records of the Royal
Society of London 15 (1960): 159?65, at p. 163.
9 Christiaan Huygens, Systema Saturnium (1650), Oeuvres Compl?tes, XV: p. 299.
10 The modern ?gures are 93 million miles and 8.8".
11 Oeuvres Compl?tes, ??: 271.
12 Hevelius to Boulliau, 9 December 1659, Paris, Biblioth?que Nationale, MSS
?Collection Boulliau? ??? (FF 13042), ?. 87r-92v, at f. 88v.
13 Ibid.
14 Systema Saturnium, Oeuvres Compl?tes, ??: p. 279.
15 Brevis Annotatio. See Oeuvres Compl?tes, ??: p. 406.
[ 41 ]
synodic period, Danish astronomer Ole R?mer, visiting astronomer at
the Paris observatory, interpreted the error as con?rmation of the ?nite
speed of light; Huygens supported him in his interpretation. Cassini, on
the other hand, thought that if this were the case, the same pattern
should be apparent in the eclipses of the other three satellites, and it was
not (surely because the elements of the orbits of these satellites had not
yet been determined as accurately as those for the ?rst satellites). Cassini
therefore accounted for the variation by making a geometric correction
to the orbit of the ?rst satellite, and then applying this as well to the or-
bits of the other three. For being on the ?wrong? side of the ?rst demon-
stration of the ?nite velocity of light, Cassini has been slated, beginning
with Edmond Halley in 1694.
Historians have treated Huygens more kindly. After all, his contri-
butions to science spoke for themselves: the pendulum clock, the ring of
Saturn, the construction of a wave front which was the foundation of
the wave theory of light, his very long telescopes, his contributions to
probability theory, and last but not least, his contributions to mathe-
matical physics. Although he was isolated in The Hague at the end of his
life, his posthumous Cosmotheoros was a best-seller in all the major Eu-
ropean languages. In that book he still maintained that Saturn?s ring was
a solid structure with a thickness of some thousands of miles, though
others (including Cassini!) had long since begun considering it as a
swarm of very small satellites?it was in this form that Saturn?s ring be-
came a model for evolutionary cosmological speculations of the second
half of the eighteenth century.
xxx
[ 40 ]
16 Ibid, 423.
17 Michelangiolo Ricci to Prince Leopold, 26 July 1660, Florence, Biblioteca
Nazionale Centrale, MSS Gal. 276, ?. 42r-42v.
18 This included a reprint of Brevis Annotatio. The full title is Christiani Hugenii
Zulichemii Brevis
19 For a full-length biographical study of Cassini, see Anna Cassini, Gio: Domen-
ico Cassini: uno scienzato del Seicento (Perinaldo: Comune di Perinaldo, 1994;
second ed., 2003.
20 Tabulae Quotidianae Revolutions macularum Iovis. Nuperrime adinventae a Ioanne
Dominico Cassino (Bologna, 1665); Martis revolutio circa axem proprium a I. D.
Cassino Telescopio I. Campani observata . . . (Bologna 1666); Ephemerides Bonon-
ienses Mediceorum Syderum (Bologna, 1668).
21 Anna Cassini, Gio: Domenico Cassini (note 19), pp. 210?211.
22 John Olmsted, ?The Scienti?c Expedition of Jean Richer to Cayenne,? Isis, 34
(1942): 117?128. See also Van Helden, Measuring the Universe: Cosmic Dimensions
from Aristarchus to Halley (Chicago: University of Chicago Press, 1985), pp.
129?143.
23 Van Helden,?Longitude and the Satellites of Jupiter,? in The Quest for Longi-
tude, ed. William J. H. Andrewes (Cambridge: Harvard University Press, 1996),
pp. 86?100, at 93?97.
c
[ 42 ]
? ? ? ? ? ? ? ?
The text of Huygens?s Ring, Cassini?s Division and Saturn?s Children was composed
in Dante, a typeface designed after World War II and completed in 1957 by Gio-
vanni Mardersteig (1892?1977), closely working with punchcutter Charles Malin
(1883?1955). Mardersteig, a printer, book designer and typeface artist, was renown
for the work produced from his two printing o?ces in Italy. He had a passion for
designing typefaces, and in conjunction with Malin, the two worked together to
produce most all of his tyepface designs, starting with Mardersteig?s earlier fonts
based on the work of Giambattista Bodoni (1740-1813). Dante was the last collab-
oration for this unique team and it embodies much of what Mardersteig learned
to make a font not only readable, but also dynamic and good-looking. The type-
face initially appeared in Boccaccio?s Trattatello in Laude di Dante in 1955, from
which it derives its name. Originally produced for hot metal composition, the
digital version that appears in this publication was redrawn from the original
characters by Ron Carpenter (b. 1950) and published by Monotype in 1993.
_